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|
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* Copyright by The HDF Group. *
* Copyright by the Board of Trustees of the University of Illinois. *
* All rights reserved. *
* *
* This file is part of HDF5. The full HDF5 copyright notice, including *
* terms governing use, modification, and redistribution, is contained in *
* the COPYING file, which can be found at the root of the source code *
* distribution tree, or in https://www.hdfgroup.org/licenses. *
* If you do not have access to either file, you may request a copy from *
* help@hdfgroup.org. *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/*
* This file contains public declarations for the H5S module.
*/
#ifndef H5Spublic_H
#define H5Spublic_H
/* Public headers needed by this file */
#include "H5public.h"
#include "H5Ipublic.h"
/* Define special dataspaces for dataset I/O operations */
#define H5S_ALL 0 /* (hid_t) */
#define H5S_BLOCK 1 /* (hid_t) */
#define H5S_PLIST 2 /* (hid_t) */
#define H5S_UNLIMITED HSIZE_UNDEF /**< Value for 'unlimited' dimensions */
/**
* The maximum dataspace rank or number of dimensions
*/
#define H5S_MAX_RANK 32
/* Flags for selection iterators */
#define H5S_SEL_ITER_GET_SEQ_LIST_SORTED \
0x0001 /**< Retrieve elements from iterator in increasing offset order, for \
* each call to retrieve sequences. Currently, this only applies to \
* point selections, as hyperslab selections are always returned in \
* increasing offset order. Note that the order is only increasing \
* for each call to H5Sget_seq_list(), the next set of sequences \
* could start with an earlier offset than the previous one. \
*/
#define H5S_SEL_ITER_SHARE_WITH_DATASPACE \
0x0002 /**< Don't copy the dataspace selection when creating the selection \
* iterator. This can improve performance of creating the iterator, \
* but the dataspace \Bold{MUST NOT} be modified or closed until the \
* selection iterator is closed or the iterator's behavior will be \
* undefined. \
*/
/**
* Types of dataspaces
*/
typedef enum H5S_class_t {
H5S_NO_CLASS = -1, /**< Error */
H5S_SCALAR = 0, /**< Singleton (scalar) */
H5S_SIMPLE = 1, /**< Regular grid */
H5S_NULL = 2 /**< Empty set */
} H5S_class_t;
/**
* Different ways of combining selections
*/
typedef enum H5S_seloper_t {
H5S_SELECT_NOOP = -1, /**< Error */
H5S_SELECT_SET = 0, /**< Select "set" operation */
H5S_SELECT_OR, /**< Binary "or" operation for hyperslabs
* (add new selection to existing selection)
* \code
* Original region: AAAAAAAAAA
* New region: BBBBBBBBBB
* A or B: CCCCCCCCCCCCCCCC
* \endcode
*/
H5S_SELECT_AND, /**< Binary "and" operation for hyperslabs
* (only leave overlapped regions in selection)
* \code
* Original region: AAAAAAAAAA
* New region: BBBBBBBBBB
* A and B: CCCC
* \endcode
*/
H5S_SELECT_XOR, /**< Binary "xor" operation for hyperslabs
* (only leave non-overlapped regions in selection)
* \code
* Original region: AAAAAAAAAA
* New region: BBBBBBBBBB
* A xor B: CCCCCC CCCCCC
* \endcode
*/
H5S_SELECT_NOTB, /**< Binary "not" operation for hyperslabs
* (only leave non-overlapped regions in original selection)
* \code
* Original region: AAAAAAAAAA
* New region: BBBBBBBBBB
* A not B: CCCCCC
* \endcode
*/
H5S_SELECT_NOTA, /**< Binary "not" operation for hyperslabs
* (only leave non-overlapped regions in new selection)
* \code
* Original region: AAAAAAAAAA
* New region: BBBBBBBBBB
* B not A: CCCCCC
* \endcode
*/
H5S_SELECT_APPEND, /**< Append elements to end of point selection */
H5S_SELECT_PREPEND, /**< Prepend elements to beginning of point selection */
H5S_SELECT_INVALID /**< Invalid upper bound on selection operations */
} H5S_seloper_t;
/**
* Selection type
*/
typedef enum {
H5S_SEL_ERROR = -1, /**< Error */
H5S_SEL_NONE = 0, /**< Empty selection */
H5S_SEL_POINTS = 1, /**< Set of points */
H5S_SEL_HYPERSLABS = 2, /**< Hyperslab */
H5S_SEL_ALL = 3, /**< Everything */
H5S_SEL_N /**< Sentinel \internal THIS MUST BE LAST */
} H5S_sel_type;
#ifdef __cplusplus
extern "C" {
#endif
/* Operations on dataspaces, dataspace selections and selection iterators */
/**
* \ingroup H5S
*
* \brief Releases and terminates access to a dataspace
*
* \space_id
*
* \return \herr_t
*
* \details H5Sclose() releases a dataspace. Further access through the
* dataspace identifier is illegal. Failure to release a dataspace with this
* call will result in resource leaks.
*
* \version 1.4.0 Fortran subroutine introduced in this release.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sclose(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Performs an operation on a hyperslab and an existing selection and
* returns the resulting selection
*
* \space_id
* \param[in] op Operation to perform on the current selection
* \param[in] start Offset of the start of of the hyperslab
* \param[in] stride Hyperslab stride
* \param[in] count Number of blocks included in the hyperslab
* \param[in] block Size of a block in the hyperslab
*
* \return \hid_tv{dataspace}
*
* \details H5Scombine_hyperslab() combines a hyperslab selection specified
* by \p start, \p stride, \p count and \p block with the current
* selection for the dataspace \p space_id, creating a new dataspace
* to return the generated selection. If the current selection is
* not a hyperslab, it is freed and the hyperslab parameters passed
* in are combined with the #H5S_SEL_ALL hyperslab (ie. a selection
* composing the entire current extent). If either \p stride or
* \p block is NULL, then it will be set to \p 1.
*
* \since 1.10.6
*
*/
H5_DLL hid_t H5Scombine_hyperslab(hid_t space_id, H5S_seloper_t op, const hsize_t start[],
const hsize_t stride[], const hsize_t count[], const hsize_t block[]);
/**
* \ingroup H5S
*
* \brief Combine two hyperslab selections with an operation, returning a
* dataspace with the resulting selection
*
* \space_id{space1_id}
* \param[in] op Selection operator
* \space_id{space2_id}
*
* \return \hid_t{dataspace}
*
* \details H5Scombine_select() combines two hyperslab selections
* \p space1_id and \p space2_id with an operation, returning a
* new dataspace with the resulting selection. The dataspace extent
* from \p space1_id is copied for the dataspace extent of the
* newly created dataspace.
*
* \since 1.10.6
*
*/
H5_DLL hid_t H5Scombine_select(hid_t space1_id, H5S_seloper_t op, hid_t space2_id);
/**
* \ingroup H5S
*
* \brief Creates an exact copy of a dataspace
*
* \space_id
*
* \return \hid_tv{dataspace}
*
* \details H5Scopy() creates a new dataspace which is an exact copy of the
* dataspace identified by \p space_id. The dataspace identifier
* returned from this function should be released with H5Sclose()
* or resource leaks will occur.
*
* \version 1.4.0 Fortran subroutine introduced.
* \since 1.0.0
*
*/
H5_DLL hid_t H5Scopy(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Creates a new dataspace of a specified type
*
* \param[in] type Type of dataspace to be created
*
* \return \hid_t{dataspace}
*
* \details H5Screate() creates a new dataspace of a particular type. Currently
* supported types are #H5S_SCALAR, #H5S_SIMPLE, and #H5S_NULL.
*
* Further dataspace types may be added later.
*
* A scalar dataspace, #H5S_SCALAR, has a single element, though that
* element may be of a complex datatype, such as a compound or array
* datatype. By convention, the rank of a scalar dataspace is always \p 0
* (zero); think of it geometrically as a single, dimensionless point,
* though that point can be complex.
*
* A simple dataspace, #H5S_SIMPLE, consists of a regular array of elements.
*
* A null dataspace, #H5S_NULL, has no data elements.
*
* The dataspace identifier returned by this function can be released with
* H5Sclose() so that resource leaks will not occur.
*
* \version 1.4.0 Fortran subroutine introduced.
* \since 1.0.0
*
*/
H5_DLL hid_t H5Screate(H5S_class_t type);
/**
* \ingroup H5S
* \brief Creates a new simple dataspace and opens it for access
*
* \param[in] rank Number of dimensions of dataspace
* \param[in] dims Array specifying the size of each dimension
* \param[in] maxdims Array specifying the maximum size of each dimension
*
* \return \hid_t{dataspace}
*
* \details H5Screate_simple() creates a new simple dataspace and opens it
* for access, returning a dataspace identifier.
*
* \p rank is the number of dimensions used in the dataspace.
*
* \p dims is a one-dimensional array of size rank specifying the
* size of each dimension of the dataset. \p maxdims is an array of
* the same size specifying the upper limit on the size of each
* dimension.
*
* Any element of \p dims can be \p 0 (zero). Note that no data can
* be written to a dataset if the size of any dimension of its current
* dataspace is \p 0. This is sometimes a useful initial state for
* a dataset.
*
* \p maxdims may be the null pointer, in which case the upper limit
* is the same as \p dims. Otherwise, no element of \p maxdims
* should be smaller than the corresponding element of \p dims.
*
* If an element of \p maxdims is #H5S_UNLIMITED, the maximum size of
* the corresponding dimension is unlimited.
*
* Any dataset with an unlimited dimension must also be chunked; see
* H5Pset_chunk(). Similarly, a dataset must be chunked if \p dims
* does not equal \p maxdims.
*
* The dataspace identifier returned from this function must be
* released with H5Sclose() or resource leaks will occur.
*
* \note Once a dataspace has been created, specific regions or elements in
* the dataspace can be selected and selections can be removed, as well.
* For example, H5Sselect_hyperslab() selects a region in a dataspace and
* H5Sselect_elements() selects array elements in a dataspace. These
* functions are used for subsetting. H5Sselect_none() removes all
* selections from a dataspace and is used in Parallel HDF5 when a process
* does not have or need to write data.
*
* \version 1.4.0 Fortran subroutine introduced.
*
* \since 1.0.0
*
*/
H5_DLL hid_t H5Screate_simple(int rank, const hsize_t dims[], const hsize_t maxdims[]);
/**
* \ingroup H5S
*
* \brief Decodes a binary object description of data space and returns a
* new object handle
*
* \param[in] buf Buffer for the data space object to be decoded
*
* \return \hid_t{dataspace}
*
* \details Given an object description of a dataspace in binary in a
* buffer, H5Sdecode() reconstructs the HDF5 data type object and
* returns a new object handle for it. The binary description of the
* object is encoded by H5Sencode(). The user is responsible for
* passing in the right buffer. The types of dataspace addressed
* in this function are null, scalar, and simple space. For a
* simple dataspace, the selection information (for example,
* hyperslab selection) is also encoded and decoded. A complex
* dataspace has not been implemented in the library.
*
* \since 1.8.0
*
*/
H5_DLL hid_t H5Sdecode(const void *buf);
/**
* \ingroup H5S
*
* \brief Encodes a data space object description into a binary buffer
*
* \space_id{obj_id}
* \param[in,out] buf Buffer for the object to be encoded into;
* If the provided buffer is NULL, only the size
* of buffer needed is returned through \p nalloc.
* \param[in,out] nalloc The size of the allocated buffer
* \fapl_id{fapl}
*
* \return \herr_t
*
* \details Given the data space identifier \p obj_id, H5Sencode2() converts
* a data space description into binary form in a buffer. Using this
* binary form in the buffer, a data space object can be
* reconstructed with H5Sdecode() to return a new object handle
* (#hid_t) for this data space.
*
* A preliminary H5Sencode2() call can be made to determine the
* size of the buffer needed. This value is returned in \p nalloc.
* That value can then be assigned to \p nalloc for a second
* H5Sencode2() call, which will retrieve the actual encoded object.
*
* If the library determines that \p nalloc is not big enough for the
* object, it simply returns the size of the buffer needed through
* \p nalloc without encoding the provided buffer.
*
* The file access property list \p fapl_id is used to control the
* encoding via the \a libver_bounds property (see
* H5Pset_libver_bounds()). If the \a libver_bounds property is missing,
* H5Sencode2() proceeds as if the \a libver_bounds property were set to
* (#H5F_LIBVER_EARLIEST, #H5F_LIBVER_LATEST). (Functionally,
* H5Sencode1() is identical to H5Sencode2() with \a libver_bounds set to
* (#H5F_LIBVER_EARLIEST, #H5F_LIBVER_LATEST).)
*
* The types of data space that are addressed in this function are
* null, scalar, and simple space. For a simple data space, the
* information on the selection, for example, hyperslab selection,
* is also encoded and decoded. A complex data space has not been
* implemented in the library.
*
* \note Motivation: This function was introduced in HDF5-1.12 as part of the
* H5Sencode() format change to enable 64-bit selection encodings and
* a dataspace selection that is tied to a file. See the \ref_news_112
* as well as the \ref_sencode_fmt_change.
*
* \since 1.12.0
*
*/
H5_DLL herr_t H5Sencode2(hid_t obj_id, void *buf, size_t *nalloc, hid_t fapl);
/**
* \ingroup H5S
*
* \brief Copies the extent of a dataspace
*
* \space_id{dst_id}
* \space_id{src_id}
*
* \return \herr_t
*
* \details H5Sextent_copy() copies the extent from \p src_id to \p dst_id.
* This action may change the type of the dataspace.
*
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sextent_copy(hid_t dst_id, hid_t src_id);
/**
* \ingroup H5S
*
* \brief Determines whether two dataspace extents are equal
*
* \space_id{space1_id}
* \space_id{space2_id}
*
* \return \htri_t
*
* \details H5Sextent_equal() determines whether the dataspace extents of
* two dataspaces, \p space1_id and \p space2_id, are equal.
*
* \since 1.8.0
*
*/
H5_DLL htri_t H5Sextent_equal(hid_t space1_id, hid_t space2_id);
/**
* \ingroup H5S
*
* \brief Retrieves a regular hyperslab selection
*
* \space_id{spaceid}
* \param[out] start Offset of the start of the regular hyperslab
* \param[out] stride Stride of the regular hyperslab
* \param[out] count Number of blocks in the regular hyperslab
* \param[out] block Size of a block in the regular hyperslab
*
* \return \herr_t
*
* \details H5Sget_regular_hyperslab() takes the dataspace identifier,
* \p spaceid, and retrieves the values of \p start, \p stride,
* \p count, and \p block for the regular hyperslab selection.
*
* A regular hyperslab selection is a hyperslab selection
* described by setting the \p offset, \p stride, \p count, and
* \p block parameters to the H5Sselect_hyperslab() call. If
* several calls to H5Sselect_hyperslab() are needed, the
* hyperslab selection is irregular.
*
* See H5Sselect_hyperslab() for descriptions of \p offset,
* \p stride, \p count, and \p block.
*
* \note If a hyperslab selection is originally regular, then becomes
* irregular through selection operations, and then becomes regular
* again, the final regular selection may be equivalent but not
* identical to the original regular selection.
*
* \since 1.10.0
*
*/
H5_DLL htri_t H5Sget_regular_hyperslab(hid_t spaceid, hsize_t start[], hsize_t stride[], hsize_t count[],
hsize_t block[]);
/**
* \ingroup H5S
*
* \brief Gets the bounding box containing the current selection
*
* \space_id{spaceid}
* \param[out] start Starting coordinates of the bounding box
* \param[out] end Ending coordinates of the bounding box, i.e., the
* coordinates of the diagonally opposite corner
*
* \return \herr_t
*
* \details H5Sget_select_bounds() retrieves the coordinates of the bounding
* box containing the current selection and places them into
* user-supplied buffers.
*
* The \p start and \p end buffers must be large enough to hold
* the dataspace rank number of coordinates.
*
* The bounding box exactly contains the selection. I.e., if a
* 2-dimensional element selection is currently defined as containing
* the points (4,5), (6,8), and (10,7), then the bounding box
* will be (4, 5), (10, 8).
*
* The bounding box calculation includes the current offset of the
* selection within the dataspace extent.
*
* Calling this function on a \a none selection will fail.
*
* \version 1.6.0 The \p start and \p end parameters have changed from type
* \p hsize_t * to \p hssize_t *.
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.2.0
*
*/
H5_DLL herr_t H5Sget_select_bounds(hid_t spaceid, hsize_t start[], hsize_t end[]);
/**
* \ingroup H5S
*
* \brief Gets the number of element points in the current selection
*
* \space_id{spaceid}
*
* \return Returns the number of element points in the current dataspace
* selection if successful. Otherwise returns a negative value.
*
* \details H5Sget_select_elem_npoints() returns the number of element
* points in the current dataspace selection, so that the element
* points can be retrieved with H5Sget_select_elem_pointlist().
* (This is similar to the way that H5Sget_select_hyper_nblocks()
* and H5Sget_select_hyper_blocklist() work with hyperslab
* selections.)
*
* Coincidentally, H5Sget_select_npoints() and
* H5Sget_select_elem_npoints() will always return the same value
* when an element selection is queried, but
* H5Sget_select_elem_npoints() does not work with other selection
* types.
*
* \since 1.2.0
*
*/
H5_DLL hssize_t H5Sget_select_elem_npoints(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Gets the list of element points currently selected
*
* \space_id{spaceid}
* \param[in] startpoint Element point to start with
* \param[in] numpoints Number of element points to get
* \param[out] buf List of element points selected
*
* \details H5Sget_select_elem_pointlist() returns the list of element
* points in the current dataspace selection \p space_id. Starting
* with the \p startpoint in the list of points, \p numpoints
* points are put into the user's buffer. If the user's buffer
* fills up before \p numpoints points are inserted, the buffer
* will contain only as many points as fit.
*
* The element point coordinates have the same dimensionality
* (rank) as the dataspace they are located within. The list of
* element points is formatted as follows:\n
* \<coordinate\>, followed by\n
* the next coordinate,\n
* etc.\n
* until all of the selected element points have been listed.
*
* The points are returned in the order they will be iterated
* through when the selection is read/written from/to disk.
*
* \since 1.2.0
*
*/
H5_DLL herr_t H5Sget_select_elem_pointlist(hid_t spaceid, hsize_t startpoint, hsize_t numpoints,
hsize_t buf[/*numpoints*/]);
/**
* \ingroup H5S
*
* \brief Gets the list of hyperslab blocks currently selected
*
* \space_id{spaceid}
* \param[in] startblock Hyperslab block to start with
* \param[in] numblocks Number of hyperslab blocks to get
* \param[out] buf List of hyperslab blocks selected
*
* \return \herr_t
*
* \details H5Sget_select_hyper_blocklist() returns a list of the hyperslab
* blocks currently selected. Starting with the \p startblock-th block
* in the list of blocks, \p numblocks blocks are put into the
* user's buffer. If the user's buffer fills up before \p numblocks
* blocks are inserted, the buffer will contain only as many blocks
* as fit.
*
* The block coordinates have the same dimensionality (rank) as the
* dataspace they are located within. The list of blocks is
* formatted as follows:\n
* \<"start" coordinate\>, immediately followed by\n
* \<"opposite" corner coordinate\>, followed by\n
* the next "start" and "opposite" coordinates,\n
* etc. until all of the selected blocks have been listed.\n
* No guarantee of any order of the blocks is implied.
*
* \since 1.2.0
*
*/
H5_DLL herr_t H5Sget_select_hyper_blocklist(hid_t spaceid, hsize_t startblock, hsize_t numblocks,
hsize_t buf[/*numblocks*/]);
/**
* \ingroup H5S
*
* \brief Get number of hyperslab blocks
*
* \space_id{spaceid}
*
* \return Returns the number of hyperslab blocks in the current dataspace
* selection if successful. Otherwise returns a negative value.
*
* \details H5Sget_select_hyper_nblocks() returns the number of hyperslab
* blocks in the current dataspace selection.
*
* \since 1.2.0
*
*/
H5_DLL hssize_t H5Sget_select_hyper_nblocks(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Determines the number of elements in a dataspace selection
*
* \space_id{spaceid}
*
* \return Returns the number of elements in the selection if successful;
* otherwise returns a negative value.
*
* \details H5Sget_select_npoints() determines the number of elements in
* the current selection of a dataspace. It works with any
* selection type, and is the correct way to retrieve the number
* of elements in a selection.
*
* \version 1.4.0 Fortran subroutine introduced in this release.
* \since 1.0.0
*
*/
H5_DLL hssize_t H5Sget_select_npoints(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Determines the type of the dataspace selection
*
* \space_id{spaceid}
*
* \return Returns the dataspace selection type, a value of the enumerated
* datatype #H5S_sel_type, if successful.
*
* \details H5Sget_select_type() retrieves the type of dataspace selection
* currently defined for the dataspace \p space_id. Valid values
* for the dataspace selection type are:
*
* <table>
* <tr>
* <td>#H5S_SEL_NONE</td>
* <td>No selection is defined</td>
* </tr>
* <tr>
* <td>#H5S_SEL_POINTS</td>
* <td>A sequence of points is selected</td>
* </tr>
* <tr>
* <td>#H5S_SEL_HYPERSLABS</td>
* <td>A hyperslab or compound hyperslab is selected</td>
* </tr>
* <tr>
* <td>#H5S_SEL_ALL</td>
* <td>The entire dataset is selected</td>
* </tr>
* </table>
*
* Otherwise returns a negative value.
*
* \since 1.6.0
*
*/
H5_DLL H5S_sel_type H5Sget_select_type(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Retrieves dataspace dimension size and maximum size
*
* \space_id
* \param[out] dims Pointer to array to store the size of each dimension
* \param[out] maxdims Pointer to array to store the maximum size of each
* dimension
*
* \return Returns the number of dimensions in the dataspace if successful;
* otherwise returns a negative value.
*
* \details H5Sget_simple_extent_dims() returns the size and maximum sizes
* of each dimension of a dataspace \p space_id through the \p dims
* and \p maxdims parameters.
*
* Either or both of \p dims and \p maxdims may be NULL.
*
* If a value in the returned array \p maxdims is #H5S_UNLIMITED (-1),
* the maximum size of that dimension is unlimited.
*
* \version 1.4.0 Fortran subroutine introduced.
* \since 1.0.0
*
*/
H5_DLL int H5Sget_simple_extent_dims(hid_t space_id, hsize_t dims[], hsize_t maxdims[]);
/**
* \ingroup H5S
*
* \brief Determines the dimensionality of a dataspace
*
* \space_id
*
* \return Returns the number of dimensions in the dataspace if successful;
* otherwise returns a negative value.
*
* \details H5Sget_simple_extent_ndims() determines the dimensionality (or
* rank) of a dataspace.
*
* \version 1.4.0 Fortran subroutine introduced.
* \since 1.0.0
*
*/
H5_DLL int H5Sget_simple_extent_ndims(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Determines the number of elements in a dataspace
*
* \space_id
*
* \return Returns the number of elements in the dataspace if successful;
* otherwise returns a negative value.
*
* \details H5Sget_simple_extent_npoints() determines the number of elements
* in a dataspace \p space_id. For example, a simple 3-dimensional
* dataspace with dimensions 2, 3, and 4 would have 24 elements.
*
* \version 1.4.0 Fortran subroutine introduced.
* \since 1.0.0
*
*/
H5_DLL hssize_t H5Sget_simple_extent_npoints(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Determines the current class of a dataspace
*
* \space_id
*
* \return Returns a dataspace class name if successful;
* otherwise #H5S_NO_CLASS (-1).
*
* \details H5Sget_simple_extent_type() determines the current class of a
* dataspace \p space_id.
*
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL H5S_class_t H5Sget_simple_extent_type(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Determines if a hyperslab selection is regular
*
* \space_id{spaceid}
*
* \return \htri_t
*
* \details H5Sis_regular_hyperslab() takes the dataspace identifier,
* \p spaceid, and queries the type of the hyperslab selection.
*
* A regular hyperslab selection is a hyperslab selection described
* by setting the offset, stride, count, and block parameters for
* a single H5Sselect_hyperslab() call. If several calls to
* H5Sselect_hyperslab() are needed, then the hyperslab selection
* is irregular.
*
* \since 1.10.0
*
*/
H5_DLL htri_t H5Sis_regular_hyperslab(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Determines whether a dataspace is a simple dataspace
*
* \space_id
*
* \return \htri_t
*
* \details H5Sis_simple() determines whether or not a dataspace is a simple
* dataspace.
*
* \note Currently, all dataspace objects are simple dataspaces; complex
* dataspace support will be added in the future.
*
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL htri_t H5Sis_simple(hid_t space_id);
/**
* \ingroup H5S
*
* \brief Refines a hyperslab selection with an operation, using a second
* hyperslab to modify it
*
* \space_id{space1_id}
* \param[in] op Selection operator
* \space_id{space2_id}
*
* \return \herr_t
*
* \details H5Smodify_select() refines an existing hyperslab selection
* \p space1_id with an operation \p op, using a second hyperslab
* \p space2_id. The first selection is modified to contain the
* result of \p space1_id operated on by \p space2_id.
*
* \since 1.10.6
*
*/
H5_DLL herr_t H5Smodify_select(hid_t space1_id, H5S_seloper_t op, hid_t space2_id);
/**
* \ingroup H5S
*
* \brief Sets the offset of a simple dataspace
*
* \space_id
* \param[in] offset The offset at which to position the selection
*
* \return \herr_t
*
* \details H5Soffset_simple() sets the offset of a simple dataspace
* \p space_id. The offset array must be the same number of
* elements as the number of dimensions for the dataspace. If the
* \p offset array is set to NULL, the offset for the dataspace is
* reset to 0.
*
* This function allows the same shaped selection to be moved to
* different locations within a dataspace without requiring it to
* be redefined.
*
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Soffset_simple(hid_t space_id, const hssize_t *offset);
/**
* \ingroup H5S
*
* \brief Closes a dataspace selection iterator
*
* \space_id{sel_iter_id}
*
* \return \herr_t
*
* \details H5Ssel_iter_close() closes a dataspace selection iterator
* specified by \p sel_iter_id, releasing its state.
*
* \since 1.12.0
*
*/
H5_DLL herr_t H5Ssel_iter_close(hid_t sel_iter_id);
/**\ingroup H5S
*
* \brief Creates a dataspace selection iterator for a dataspace's selection
*
* \space_id{spaceid}
* \param[in] elmt_size Size of element in the selection
* \param[in] flags Selection iterator flag
*
* \return \hid_t{valid dataspace selection iterator}
*
* \details H5Ssel_iter_create() creates a selection iterator and initializes
* it to start at the first element selected in the dataspace.
*
* \since 1.12.0
*
*/
H5_DLL hid_t H5Ssel_iter_create(hid_t spaceid, size_t elmt_size, unsigned flags);
/**
* \ingroup H5S
*
* \brief Retrieves a list of offset / length sequences for the elements in
* an iterator
*
* \space_id{sel_iter_id}
* \param[in] maxseq Maximum number of sequences to retrieve
* \param[in] maxbytes Maximum number of bytes to retrieve in sequences
* \param[out] nseq Number of sequences retrieved
* \param[out] nbytes Number of bytes retrieved, in all sequences
* \param[out] off Array of sequence offsets
* \param[out] len Array of sequence lengths
*
* \return \herr_t
*
* \details H5Ssel_iter_get_seq_list() retrieves a list of offset / length
* pairs (a list of "sequences") matching the selected elements for
* an iterator \p sel_iter_id, according to the iteration order for
* the iterator. The lengths returned are in bytes, not elements.
*
* Note that the iteration order for "all" and "hyperslab"
* selections is row-major (i.e. "C-ordered"), but the iteration
* order for "point" selections is "in order selected", unless the
* #H5S_SEL_ITER_GET_SEQ_LIST_SORTED flag is passed to
* H5Ssel_iter_create() for a point selection.
*
* \p maxseq and \p maxbytes specify the most sequences or bytes
* possible to place into the \p off and \p len arrays. \p nseq and
* \p nbytes return the actual number of sequences and bytes put
* into the arrays.
*
* Each call to H5Ssel_iter_get_seq_list() will retrieve the next
* set of sequences for the selection being iterated over.
*
* The total number of bytes possible to retrieve from a selection
* iterator is the \p elmt_size passed to H5Ssel_iter_create()
* multiplied by the number of elements selected in the dataspace
* the iterator was created from (which can be retrieved with
* H5Sget_select_npoints(). When there are no further sequences of
* elements to retrieve, calls to this routine will set \p nseq
* and \p nbytes to zero.
*
* \since 1.12.0
*
*/
H5_DLL herr_t H5Ssel_iter_get_seq_list(hid_t sel_iter_id, size_t maxseq, size_t maxbytes, size_t *nseq,
size_t *nbytes, hsize_t *off, size_t *len);
/**
* \ingroup H5S
*
* \brief Resets a dataspace selection iterator back to an initial state
*
* \param[in] sel_iter_id Identifier of the dataspace selection iterator
* to reset
* \param[in] space_id Identifier of the dataspace with selection to
* iterate over
*
* \return \herr_t
*
* \details H5Ssel_iter_reset() resets a dataspace selection iterator back to
* an initial state so that the iterator may be used for iteration
* once again.
*
* \since 1.12.1
*
*/
H5_DLL herr_t H5Ssel_iter_reset(hid_t sel_iter_id, hid_t space_id);
/**
* \ingroup H5S
*
* \brief Adjusts a selection by subtracting an offset
*
* \space_id{spaceid}
* \param[in] offset Offset to subtract
*
* \return \herr_t
*
* \details H5Sselect_adjust() shifts a dataspace selection by a specified
* logical offset within the dataspace extent.
*
* \note This can be useful for VOL developers to implement chunked datasets.
*
* \since 1.10.6
*/
H5_DLL herr_t H5Sselect_adjust(hid_t spaceid, const hssize_t *offset);
/**
* \ingroup H5S
*
* \brief Selects an entire dataspace
*
* \space_id{spaceid}
*
* \return \herr_t
*
* \details H5Sselect_all() selects the entire extent of the dataspace
* \p dspace_id.
*
* More specifically, H5Sselect_all() sets the selection type to
* #H5S_SEL_ALL, which specifies the entire dataspace anywhere it
* is applied.
*
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sselect_all(hid_t spaceid);
/**
* \ingroup H5S
*
* \brief Copies a selection from one dataspace to another
*
* \space_id{dst_id}
* \space_id{src_id}
*
* \return \herr_t
*
* \details H5Sselect_copy() copies all selection information (including
* offset) from the source dataspace \p src_id to the destination
* dataspace \p dst_id.
*
* \since 1.10.6
*
*/
H5_DLL herr_t H5Sselect_copy(hid_t dst_id, hid_t src_id);
/**
* \ingroup H5S
*
* \brief Selects array elements to be included in the selection for a
* dataspace
*
* \space_id
* \param[in] op Operator specifying how the new selection is to be
* combined with the existing selection for the dataspace
* \param[in] num_elem Number of elements to be selected
* \param[in] coord A pointer to a buffer containing a serialized copy of
* a 2-dimensional array of zero-based values specifying
* the coordinates of the elements in the point selection
*
* \return \herr_t
*
* \details H5Sselect_elements() selects array elements to be included in
* the selection for the \p space_id dataspace. This is referred
* to as a point selection.
*
* The number of elements selected is set in the \p num_elements
* parameter.
*
* The \p coord parameter is a pointer to a buffer containing a
* serialized 2-dimensional array of size \p num_elements by the
* rank of the dataspace. The array lists dataset elements in the
* point selection; that is, it’s a list of of zero-based values
* specifying the coordinates in the dataset of the selected
* elements. The order of the element coordinates in the \p coord
* array specifies the order in which the array elements are
* iterated through when I/O is performed. Duplicate coordinate
* locations are not checked for. See below for examples of the
* mapping between the serialized contents of the buffer and the
* point selection array that it represents.
*
* The selection operator \p op determines how the new selection
* is to be combined with the previously existing selection for
* the dataspace. The following operators are supported:
*
* <table>
* <tr>
* <td>#H5S_SELECT_SET</td>
* <td>Replaces the existing selection with the parameters from
* this call. Overlapping blocks are not supported with this
* operator. Adds the new selection to the existing selection.
* </td>
* </tr>
* <tr>
* <td>#H5S_SELECT_APPEND</td>
* <td>Adds the new selection following the last element of the
* existing selection.</td>
* </tr>
* <tr>
* <td>#H5S_SELECT_PREPEND</td>
* <td>Adds the new selection preceding the first element of the
* existing selection.</td>
* </tr>
* </table>
*
* <b>Mapping the serialized \p coord buffer to a 2-dimensional
* point selection array:</b>
* To illustrate the construction of the contents of the \p coord
* buffer, consider two simple examples: a selection of 5 points in
* a 1-dimensional array and a selection of 3 points in a
* 4-dimensional array.
*
* In the 1D case, we will be selecting five points and a 1D
* dataspace has rank 1, so the selection will be described in a
* 5-by-1 array. To select the 1st, 14th, 17th, 23rd, 8th elements
* of the dataset, the selection array would be as follows
* (remembering that point coordinates are zero-based):
* \n 0
* \n 13
* \n 16
* \n 22
* \n 7
*
* This point selection array will be serialized in the \p coord
* buffer as:
* \n 0 13 16 22 7
*
* In the 4D case, we will be selecting three points and a 4D
* dataspace has rank 4, so the selection will be described in a
* 3-by-4 array. To select the points (1,1,1,1), (14,6,12,18), and
* (8,22,30,22), the point selection array would be as follows:
* \n 0 0 0 0
* \n 13 5 11 17
* \n 7 21 29 21
*
* This point selection array will be serialized in the \p coord
* buffer as:
* \n 0 0 0 0 13 5 11 17 7 21 29 21
*
* \version 1.6.4 C coord parameter type changed to \p const hsize_t.
* \version 1.6.4 Fortran \p coord parameter type changed to \p INTEGER(HSIZE_T).
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sselect_elements(hid_t space_id, H5S_seloper_t op, size_t num_elem, const hsize_t *coord);
/**
* \ingroup H5S
*
* \brief Selects a hyperslab region to add to the current selected region
*
* \space_id
* \param[in] op Operation to perform on current selection
* \param[in] start Offset of start of hyperslab
* \param[in] stride Hyperslab stride
* \param[in] count Number of blocks included in hyperslab
* \param[in] block Size of block in hyperslab
*
* \return \herr_t
*
* \details H5Sselect_hyperslab() selects a hyperslab region to add to the
* current selected region for the dataspace specified by
* \p space_id.
*
* The \p start, \p stride, \p count, and \p block arrays must be the
* same size as the rank of the dataspace. For example, if the
* dataspace is 4-dimensional, each of these parameters must be a
* 1-dimensional array of size 4.
*
* The selection operator \p op determines how the new selection
* is to be combined with the already existing selection for the
* dataspace. The following operators are supported:
*
* <table>
* <tr>
* <td>#H5S_SELECT_SET</td>
* <td>Replaces the existing selection with the
* parameters from this call. Overlapping blocks
* are not supported with this operator.</td>
* </tr>
* <tr>
* <td>#H5S_SELECT_OR</td>
* <td>Adds the new selection to the existing selection.
* (Binary OR)</td>
* </tr>
* <tr>
* <td>#H5S_SELECT_AND</td>
* <td>Retains only the overlapping portions of the
* new selection and the existing selection.
* (Binary AND)</td>
* </tr>
* <tr>
* <td>#H5S_SELECT_XOR</td>
* <td>Retains only the elements that are members of
* the new selection or the existing selection,
* excluding elements that are members of both
* selections. (Binary exclusive-OR, XOR)
* </td>
* </tr>
* <tr>
* <td>#H5S_SELECT_NOTB</td>
* <td>Retains only elements of the existing selection
* that are not in the new selection.</td>
* </tr>
* <tr>
* <td>#H5S_SELECT_NOTA</td>
* <td>Retains only elements of the new selection that
* are not in the existing selection.</td>
* </tr>
* </table>
*
* The \p start array specifies the offset of the starting element
* of the specified hyperslab.
*
* The \p stride array chooses array locations from the dataspace with
* each value in the \p stride array determining how many elements to
* move in each dimension. Setting a value in the \p stride array to
* \p 1 moves to each element in that dimension of the dataspace;
* setting a value of \p 2 in allocation in the \p stride array moves
* to every other element in that dimension of the dataspace. In
* other words, the \p stride determines the number of elements to
* move from the \p start location in each dimension. Stride values
* of \p 0 are not allowed. If the \p stride parameter is NULL, a
* contiguous hyperslab is selected (as if each value in the \p stride
* array were set to \p 1).
*
* The \p count array determines how many blocks to select from the
* dataspace, in each dimension.
*
* The \p block array determines the size of the element block
* selected from the dataspace. If the \p block parameter is set to
* NULL, the block size defaults to a single element in each dimension
* (as if each value in the \p block array were set to \p 1).
*
* For example, consider a 2-dimensional dataspace with hyperslab
* selection settings as follows: the \p start offset is specified as
* [1,1], \p stride is [4,4], \p count is [3,7], and \p block is [2,2].
* In C, these settings will specify a hyperslab consisting of 21
* 2x2 blocks of array elements starting with location (1,1) with the
* selected blocks at locations (1,1), (5,1), (9,1), (1,5), (5,5), etc.;
* in Fortran, they will specify a hyperslab consisting of 21 2x2
* blocks of array elements starting with location (2,2) with the
* selected blocks at locations (2,2), (6,2), (10,2), (2,6), (6,6), etc.
*
* Regions selected with this function call default to C order
* iteration when I/O is performed.
*
* \version 1.4.0 Fortran subroutine introduced in this release.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sselect_hyperslab(hid_t space_id, H5S_seloper_t op, const hsize_t start[],
const hsize_t stride[], const hsize_t count[], const hsize_t block[]);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Checks if current selection intersects with a block
*
* \space_id
* \param[in] start Starting coordinate of block
* \param[in] end Opposite ("ending") coordinate of block
*
* \return \htri_t
*
* \details H5Sselect_intersect_block() checks to see if the current
* selection \p space_id in the dataspace intersects with the block
* specified by \p start and \p end.
*
* \note Assumes that \p start & \p end block bounds are inclusive, so
* \p start == \p end value is OK.
*
* \since 1.10.6
*
*/
H5_DLL htri_t H5Sselect_intersect_block(hid_t space_id, const hsize_t *start, const hsize_t *end);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Resets the selection region to include no elements
*
* \space_id{spaceid}
*
* \return \herr_t
*
* \details H5Sselect_none() resets the selection region for the dataspace
* \p space_id to include no elements.
*
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sselect_none(hid_t spaceid);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Projects the intersection of two source selections to a
* destination selection
*
* \space_id{src_space_id}
* \space_id{dst_space_id}
* \space_id{src_intersect_space_id}
*
* \return Returns a dataspace with a selection equal to the intersection of
* \p src_intersect_space_id and \p src_space_id projected from
* \p src_space to \p dst_space on success, negative on failure.
*
* \details H5Sselect_project_intersection() computes the intersection
* between two dataspace selections and projects that intersection
* into a third selection.This can be useful for VOL developers to
* implement chunked or virtual datasets.
*
* \since 1.10.6
*
*/
H5_DLL hid_t H5Sselect_project_intersection(hid_t src_space_id, hid_t dst_space_id,
hid_t src_intersect_space_id);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Checks if two selections are the same shape
*
* \space_id{space1_id}
* \space_id{space2_id}
*
* \return \htri_t
*
* \details H5Sselect_shape_same() checks to see if the current selection
* in the dataspaces are the same dimensionality and shape.
*
* This is primarily used for reading the entire selection in
* one swoop.
*
* \since 1.10.6
*
*/
H5_DLL htri_t H5Sselect_shape_same(hid_t space1_id, hid_t space2_id);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Verifies that the selection is within the extent of the dataspace
*
* \space_id{spaceid}
*
* \return \htri_t
*
* \details H5Sselect_valid() verifies that the selection for the dataspace
* \p space_id is within the extent of the dataspace if the current
* offset for the dataspace is used.
*
* \version 1.4.0 Fortran subroutine introduced in this release.
* \since 1.0.0
*
*/
H5_DLL htri_t H5Sselect_valid(hid_t spaceid);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Resets the extent of a dataspace back to "none"
*
* \space_id
*
* \return \herr_t
*
* \details H5Sset_extent_none() resets the type of a dataspace to
* #H5S_NULL with no extent information stored for the dataspace.
*
* \version 1.10.7, 1.12.1 The function behavior changed. The previous
* behavior was to set the class to #H5S_NO_CLASS.
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sset_extent_none(hid_t space_id);
/*--------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Sets or resets the size of an existing dataspace
*
* \space_id
* \param[in] rank Rank, or dimensionality, of the dataspace
* \param[in] dims Array containing current size of dataspace
* \param[in] max Array containing maximum size of dataspace
*
* \return \herr_t
*
* \details H5Sset_extent_simple() sets or resets the size of an existing
* dataspace.
*
* \p dims is an array of size \p rank which contains the new size
* of each dimension in the dataspace. \p max is an array of size
* \p rank which contains the maximum size of each dimension in
* the dataspace.
*
* Any previous extent is removed from the dataspace, the dataspace
* type is set to #H5S_SIMPLE, and the extent is set as specified.
*
* \version 1.4.0 Fortran subroutine was introduced.
* \since 1.0.0
*
*/
H5_DLL herr_t H5Sset_extent_simple(hid_t space_id, int rank, const hsize_t dims[], const hsize_t max[]);
/* Symbols defined for compatibility with previous versions of the HDF5 API.
*
* Use of these symbols is deprecated.
*/
#ifndef H5_NO_DEPRECATED_SYMBOLS
/* Function prototypes */
/* --------------------------------------------------------------------------*/
/**\ingroup H5S
*
* \brief Encodes a data space object description into a binary buffer
*
* \space_id{obj_id}
* \param[in,out] buf Buffer for the object to be encoded into;
* If the provided buffer is NULL, only the size of
* buffer needed is returned through \p nalloc.
* \param[in,out] nalloc The size of the allocated buffer
*
* \return \herr_t
*
* \deprecated Deprecated in favor of H5Sencode2()
*
* \details Given the data space identifier \p obj_id, H5Sencode1() converts
* a data space description into binary form in a buffer. Using
* this binary form in the buffer, a data space object can be
* reconstructed using H5Sdecode() to return a new object handle
* (\p hid_t) for this data space.
*
* A preliminary H5Sencode1() call can be made to find out the size
* of the buffer needed. This value is returned as \p nalloc. That
* value can then be assigned to \p nalloc for a second H5Sencode1()
* call, which will retrieve the actual encoded object.
*
* If the library finds out \p nalloc is not big enough for the
* object, it simply returns the size of the buffer needed through
* \p nalloc without encoding the provided buffer.
*
* The types of data space addressed in this function are null,
* scalar, and simple space. For a simple data space, the information
* on the selection, for example, hyperslab selection, is also
* encoded and decoded. A complex data space has not been
* implemented in the library.
*
* \version 1.12.0 The function H5Sencode() was renamed H5Sencode1() and
* deprecated.
* \since 1.8.0
*
*/
H5_DLL herr_t H5Sencode1(hid_t obj_id, void *buf, size_t *nalloc);
#endif /* H5_NO_DEPRECATED_SYMBOLS */
#ifdef __cplusplus
}
#endif
#endif /* H5Spublic_H */
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